Display panel, manufacturing method thereof, driving method and display device

ABSTRACT

A display panel includes a first display sub-panel and a second display sub-panel disposed opposite to each other, the first display sub-panel including a plurality of first gate lines and the second display sub-panel including a plurality of second gate lines. The display panel further includes a plurality of single-way conducting switches, the first gate lines, the second gate lines and the single-way conducting switches being disposed in one-to-one correspondence, each of the single-way conducting switches having an input end which is electrically connected to the corresponding first gate line and an output end which is electrically connected to the corresponding second gate line, and each of the single-way conducting switches being unidirectionaly conducted from the corresponding first gate line to the corresponding second gate line.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit of and priority to ChinesePatent Application No. 201810997011.X filed Aug. 29, 2018, the entirecontents of which being incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to the field of display technologies, andmore particularly, to a display panel, a manufacturing method thereof, adriving method, and a display device.

BACKGROUND

A double-sided display device is a display device that includes adouble-sided display. Presently, double-sided display devices have avery vast market foreground and these devices are mainly applied to roadsign boards, communication tools (such as mobile phones), and windowinteraction tools (such as government windows, financial enterprisewindows). A common double-sided display device is formed by bonding twodisplay panels arranged opposite to one another, which has a relativelycomplicated driving process. When the synchronous display of the twodisplay panels is performed, the asynchronous display of two screenscommonly occurs and, as such, there is a problem of poor displaysynchronization.

SUMMARY

An embodiment of the present disclosure provides a display panel,comprising: a first display sub-panel and a second display sub-paneldisposed opposite to each other, the first display sub-panel comprisinga plurality of first gate lines and the second display sub-panelcomprising a plurality of second gate lines, wherein the display panelfurther comprises a plurality of single-way conducting switches, thefirst gate lines, the second gate lines and the single-way conductingswitches being disposed in one-to-one correspondence, each of thesingle-way conducting switches having an input end which is electricallyconnected to the corresponding first gate line and an output end whichis electrically connected to the corresponding second gate line, andeach of the single-way conducting switches being unidirectionalyconducted from the corresponding first gate line to the correspondingsecond gate line.

The display panel provided by the present disclosure disposes thesingle-way conducting switch which is connected between each of thefirst gate lines and the second gate line corresponding thereto. Whenthe double-sided synchronous display of the display panel is required, agate scan signal is sent to the first gate line of the displaysub-panel, but no signal or a cutoff signal is inputted to the secondgate line of the second display sub-panel. The single-way conductingswitch, at this time, is turned on and the second gate linecorresponding to the first gate line is also synchronously inputted withthe gate scan signal by the connection to the single-way conductingswitch.

An embodiment of the present disclosure further provides a method formanufacturing a display panel, comprising: providing a base substratehaving a first surface and a second surface, which is opposite to thefirst surface; forming a first stacked structure on the first surface;forming a second stacked structure on the second surface; wherein astructure consisted of the first stacked structure, the base substrateand the second stacked structure comprises a first display sub-panel anda second display sub-panel disposed opposite to each other and aplurality of single-way conducting switches; wherein, the first displaysub-panel comprises a plurality of first gate lines and the seconddisplay sub-panel comprises a plurality of second gate lines, the firstgate lines, the second gate lines and the single-way conducting switchesare provided in one-to-one correspondence, each of the single-wayconducting switches comprises an input end which is electricallyconnected to the corresponding first gate line and an output end whichis electrically connected to the corresponding second gate line; each ofthe single-way conducting switches is unidirectionally conducted fromthe first gate line to the second gate line corresponding thereto.

An embodiment of the present disclosure further provides a drivingmethod for a display panel being used for driving the display panelprovided in the first aspect, comprising: when the simultaneous displayof the first display sub-panel and the second display sub-panel isperformed, inputting a first gate scan signal to the first gate line ofthe first display sub-panel and enabling the display of the firstdisplay sub-panel; and the gate scan signal driving the correspondingsingle-way conducting switch to be unidirectionally turned on from thefirst gate line to the second gate line of the second display sub-panel,and allowing the simultaneous display of the second display sub-paneland the first display sub-panel.

An embodiment of the present disclosure further provides a displaydevice comprising the above described display panel.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to illustrate the technical resolutions of the embodiments ofthe disclosure more clearly, a brief introduction may be givenhereinafter to the accompany drawings that may be used in thedescription of the embodiments. Notably, the drawings in the descriptionbelow are merely for illustrating some embodiments of the presentdisclosure, and other drawings may be obtained by those skilled in theart according to these drawings without any creative labor.

FIG. 1 is a schematic diagram of a circuit of a display panel accordingto an embodiment of the present disclosure.

FIG. 2 is a schematic diagram of a through-hole of a wiring area of adisplay panel according to an embodiment of the present disclosure.

FIG. 3 is a schematic diagram of another circuit of a display panelaccording to an embodiment of the present disclosure.

FIG. 4 is a schematic diagram of a circuit with a source driver chip ofa display panel according to an embodiment of the present disclosure.

FIG. 5 is a schematic diagram of another circuit with a source driverchip according to an embodiment of the present disclosure.

FIG. 6 is a block diagram of a kind of display panel according to anembodiment of the present disclosure.

FIG. 7 is a block diagram of another kind of display panel according toan embodiment of the present disclosure.

FIG. 8 is a block diagram of another kind of display panel according toan embodiment of the present disclosure.

FIG. 9 is a block diagram of another kind of display panel according toan embodiment of the present disclosure.

DETAILED DESCRIPTION

A clear and through description will be given to the technical solutionof the present disclosure with reference to the accompanying drawings ofthe present disclosure. Understandably, the illustrated embodiments arenot all of the embodiments of the present disclosure, but only a part ofthem. According to the embodiments of the present disclosure, all of theother embodiments obtained by those skilled in the art without consumingany creative work fall within the protection scope of the presentdisclosure.

Referring to FIG. 1, a display panel in an embodiment of the presentdisclosure includes a first display sub-panel 1 and a second displaysub-panel 2 which are disposed opposite to each other. The first displaysub-panel 1 includes a plurality of first gate lines 101 and the seconddisplay sub-panel 2 includes a plurality of second gate lines 201. Thedisplay panel further includes a plurality of single-way conductingswitches 3, each of which is connected to one of the first gate lines101 and one of the second gate lines 201, respectively. Each of thesingle-way conducting switches 3 has an input end which is electricallyconnected to the corresponding first gate line 101 and an output endwhich is electrically connected to the corresponding second gate line201. Further, each single-way conducting switch 3 is unidirectionallyconducted from the corresponding first gate line 101 to thecorresponding second gate line 201.

The display panel provided by the embodiment of the present disclosuredisposes the single-way conducting switch 3 which is connected betweeneach of the first gate lines 101 and the second gate line 201corresponding thereto. When the double-sided synchronous display of thedisplay panel is required, a gate scan signal is sent to the first gateline 101 of the display sub-panel 1, but no signal or a cutoff signal isinputted to the second gate line 201 of the second display sub-panel 2.The single-way conducting switch 3, at this time, is turned on and thesecond gate line 201 corresponding to the first gate line 101 is alsosynchronously inputted with the gate scan signal by the connection tothe single-way conducting switch 3, which allows the synchronous displayof the first display sub-panel 1 and the second display sub-panel 2 andimproves the synchronization and consistency of screen when the displaysub-panel 1 and the second display sub-panel 2 are simultaneouslydisplayed. It should be noted that the cutoff signal or a cutoff voltagedescribed in the embodiment of the present disclosure is a low levelsignal such as a grounding signal. The single-way conducting switch 3 isunidirectionally conducted from the input end to the output end thereofin the embodiment of the present disclosure. For example, when thesingle-way conducting switch 3 is a P-N junction, it is unidirectionallyconducted from a P-region 301 (input end) to an N-region 302 (outputend) of the P-N junction.

Referring to FIG. 2, the foregoing single-way conducting switch 3 may bea P-N junction in some embodiments, the P-region 301 of which isconnected to the first gate line 101 corresponding thereto and theN-region 302 of which is connected to the second gate line 201corresponding thereto.

Referring to FIG. 2, the display panel further includes a spacer layer 4interposed between the first display sub-panel 1 and the second displaysub-panel 2 in some embodiments. The spacer layer 4 is provided with aplurality of through-holes 5, which correspond to the single-wayconducting switches 3 one by one and also correspond to wiring areas ofthe first display sub-panel 1 and the second display sub-panel 2. Itshould be noted that the display panel includes a display area and aframe area. The gate lines and data lines in the display area areprovided in the frame area through wire bonding, that is to say, theframe area outside the display area is the wiring area in the embodimentof the present disclosure. In addition, it should be noted that FIG. 2only shows one through-hole 5 in the wiring area and the first gate line101 as well as the second gate line 201 with which the through-hole 5 iscommunicating, but it does not show any other structures as provided inthe first display sub-panel 1 and the second display sub-panel 2.

Each of the single-way conducting switches 3 can be provided in thethrough-hole 5 corresponding thereto or in the wiring area of the firstdisplay sub-panel 1. By passing through the through-hole 5 correspondingthereto, the output end of each single-way conducting switch 3 iselectrically connected to the second gate line 201 correspondingthereto. In this case, a line for the connection of the single-wayconducting switch 3 and the second gate line 201 is disposed in thecorresponding through-hole 5. When located in the wiring area of thefirst display sub-panel 1, each of the single-way conducting switches 3may also be integrated into a gate drive circuit to which each of thefirst gate lines 101 is connected. In addition, each of the single-wayconducting switches 3 can also be located in the wiring area of thesecond display sub-panel 2. Through the through-hole 5 correspondingthereto, the input end of each of the single-way conducting switches 3is electrically connected to the first gate line 101 correspondingthereto. In this case, a line for the connection of the single-wayconducting switch 3 and the first gate line 101 is disposed in thethrough-hole 5 corresponding thereto.

The gate drive circuit may be a shift register unit, for example, a GOAunit. Gate Driver on Array (GOA) is a technology for the integration ofa gate drive circuit on an array substrate. Pixel units are periodicallyarranged in the array substrate. Each of the pixel units may include aswitch tube and a pixel electrode and each of the pixel electrodes or alight emitting device 8 is driven by connecting a data line and a gateline to the switch tube. The switch tube may be a thin film transistorand have a source electrode to which the data line is connected, as wellas a gate electrode to which the gate line is connected and a drainelectrode to which the pixel electrode is connected. The GOA unit isused as a shift register unit to drive the switch tube in thisembodiment.

When the gate drive circuit is the GOA unit, as shown in FIG. 1, thefirst display sub-panel 1 further includes a plurality of first GOAunits (GOA11˜GOA14 in FIG. 1) which are disposed in the wiring areas ofthe first display sub-panel 1 and the first GOA units are electricallyconnected to the first gate lines 101 in one-to-one correspondence insome embodiments. In order to more clearly indicate correspondencebetween the GOA unit and the gate lines, referring to FIG. 1, the firstgate line numbered Gate11 corresponds to GOA11, while the first gateline numbered Gate12 corresponds to GOA12, the first gate line numberedGate13 corresponds to GOA13, and the gate line numbered Gate14corresponds to GOA14. The second display sub-panel 2 further includes aplurality of second GOA units (GOA21˜GOA24 in FIG. 1) which are disposedin the wiring areas of the second display sub-panel 2 and the second GOAunits are electrically connected to the second gate lines 201 inone-to-one correspondence. In order to clearly denote correspondencebetween the GOA unit and the second gate lines, referring to FIG. 1, thesecond gate line numbered Gate 21 corresponds to GOA21, while the secondgate line numbered Gate 22 corresponds to GOA22, the second gate linenumbered Gate23 corresponds to GOA23, and the gate line numbered Gate24corresponds to GOA24. The input end of each of the single-way conductingswitches 3 is electrically connected to the first GOA unit and the firstgate line 101 corresponding thereto and the output end thereof iselectrically connected to the second gate line 201 correspondingthereto.

Each of the first gate lines 101 is connected to a plurality of firstswitch tubes in a row where the first gate line 101 is arranged,specifically, to a first gate electrode of the first switch tubes. Eachof the second gate lines 201 is connected to a second gate electrode ofa plurality of second switch tubes in a row where the second gate line201 is arranged.

The gate drive circuit may also be a gate driver chip, which may bebound to the array substrate and connected to a gate electrode through agate line. As shown in FIG. 3, a first gate driver chip 115 is used as adriving circuit of a first gate electrode and has a plurality of outputends, each of which is connected to one of the first gate lines 101,respectively. Similarly, a second gate driver chip 215 is used as adriving circuit of a second gate electrode and has a plurality of outputends, each of which is connected to one of the second gate lines 201,respectively. When the gate driver chip is used as the gate drivecircuit, as shown in FIG. 3, the single-way conducting switch 3 may bedisposed between the first display sub-panel 1 and the second displaysub-panel 2 and located in the through-hole 5. Alternatively, thesingle-way conducting switch 3 may be disposed in the wiring area of thefirst display sub-panel 1 to be integrated with or separate from thefirst gate driver chip 115.

It should be noted that only four groups of the first and second gatelines are exemplarily illustrated in FIGS. 1 and 3, however, there are aplurality of groups of the first and gate lines disposed on the wiringarea of the display panel in one-to-one correspondence.

The display panel in the embodiment of the present disclosure also hasthe advantage of reducing power consumption during synchronous display.The synchronous display of the first display sub-panel 1 and the seconddisplay sub-panel 2 may be implemented by sending a gate scan signal tothe first gate line 101 of the first display sub-panel 1 without anysignal input to the second gate line 201 of the second display sub-panel2. In this case, the first gate driver chip 115 (or each of the firstGOA unit) has a signal output but the second gate driver chip 215 (oreach of the second GOA units) is in a sleep state, and only the gatedrive circuit of the first display sub-panel 1 is operating, therebyreducing the power consumption of the display panel.

As shown in FIGS. 1 and 3, in some embodiments, the second displaysub-panel 2 further includes a plurality of voltage stabilizingresistors R which are disposed in the wiring area of the second displaysub-panel 2 and a plurality of short-circuit branches 217. The voltagestabilizing resistors R and the single-way conducting switches 3 are inone-to-one correspondence and each of the voltage stabilizing resistorsR has one end which is electrically connected to the second GOA unitcorresponding thereto and the other end which is electrically connectedto the output end of the single-way conducting switch 3 correspondingthereto. The short-circuit branches 217 are disposed in the wiring areaof the second display sub-panel 2 and are in one-to-one correspondenceto the voltage stabilizing resistors R and each of the short-circuitbranches 217 is connected in parallel to both ends of the voltagestabilizing resistor R corresponding thereto. In a specificimplementation, two output ends may be provided in the GOA unit, whereinthe first output end is connected to the voltage stabilizing resistor Rand the second output end is connected to the short-circuit branch 217.Whether or not to output a signal from the first output end iscontrolled by a circuit and a clock signal within the GOA unit, so as tocontrol the turn-on or turn-off of the voltage stabilizing resistor R,and whether or not to output a signal from the second output end iscontrolled by a circuit and a clock signal within the GOA unit, so as tocontrol the turn-on or turn-off of the short-circuit branch 217.

For an instance, the GOA units may be a gate drive circuit. When thefirst display sub-panel 1 and the second display sub-panel 2 aresimultaneously displayed, a first gate scan signal is outputted from thefirst GOA units but no signal or only a cutoff signal is outputted fromthe second GOA units. The single-way conducting switch 3 correspondingto them, at this time, has a voltage difference between its input endand output end, so the single-way conducting switch 3 is turned on. Whenthere is no voltage stabilizing resistor R provided, since no signal oronly a cutoff signal is outputted from the second GOA units, voltage atthe output end of the single-way conducting switch 3 is pulled down andvoltage of a data signal of each of the second gate electrodes to whichthe second gate line 201 is connected is pulled down to be lower than aturn-on voltage of the second gate electrode, so that the second gateelectrode cannot be turned on. When a voltage stabilizing resistor R isprovided, the short-circuit branch 217 is disconnected when thesynchronous display is performed so as to keep the conducting of thevoltage stabilizing resistor R. A appropriate type of resistor may beselected to maintain voltage inputted to each of the second gateelectrodes at an appropriate value, which is neither higher than voltageof the first gate scan signal to unable to conduct the single-wayconducting switch nor lower than the turn-on voltage of each of thesecond gate electrodes, so as to ensure the normal turn-on of each ofthe second gate electrodes and smoothly realize the double-sidedsynchronous display.

In some embodiments, the above voltage stabilizing resistors may bedirectly connected to a grounding signal other than the gate drivecircuit. That is to say, one end of each of the voltage stabilizingresistors R is electrically connected to the grounding signal and aswitch which controls on and off of the voltage stabilizing resistor Ris interposed between the voltage stabilizing resistor R and thegrounding signal. The other end of each of the voltage stabilizingresistors R is electrically connected to the output end of thesingle-way conducting switch 3 corresponding thereto. A plurality ofshort-circuit branches 217 are disposed in the wiring area of the seconddisplay sub-panel 2 and are in one-to-one correspondence to the voltagestabilizing resistors R. Each short-circuit branch 217 has one end whichis connected to a second gate drive circuit and the other end which isconnected to the second gate line. The on and off of the voltagestabilizing resistor R are controlled by the switch between the voltagestabilizing resistor R and the grounding signal and the on and off ofthe short-circuit branch is controlled by the second gate drive circuit(the second GOA unit or a second gate starting chip 215). The operationprinciple of the circuit refers to the operation principle of thecircuit shown in FIGS. 1 and 3, and repetitive descriptions will not beelaborated herein.

The above-described voltage stabilizing resistors R may be fixedresistors or variable resistors. In practical applications, a resistancevalue of the voltage-stabilizing resistors R may be determined byreasonable test and calculation and may be ranged from several ohms toseveral megaohms. For example, a display panel of a device such as amobile phone has a resistance of less than 10Ω and a 60-inch TV may havea resistance in the order of magnitude of kiloohm (kΩ), megaohm (MΩ).

The first display sub-panel 1 further includes a plurality of first datalines 116 and the second display sub-panel 2 further includes aplurality of second data lines 216 in some embodiments. It should benoted that FIGS. 4-5 only show a schematic circuit diagram of a displaypanel having a source driver chip 7 by taking an example of a group ofthe first GOA unit and first gate line in the first display sub-panel 1as well as a group of the second GOA unit and second gate line in thesecond display sub-panel 2 corresponding thereto. Furthermore, FIGS. 4and 5 only exemplarily show a first data line 116 and a second data line216. As shown in FIG. 4, the display panel includes two source driverchips, which are a first source driver chip 701 and a second sourcedriver chip 702 in some embodiments. The first source driver chip 701 iselectrically connected to a plurality of first data lines 116 and thesecond source driver chip 702 is electrically connected to a pluralityof second data lines 216. The above-described two source driver chipsmay input different data signals to the first data lines 116 and thesecond data lines 216, respectively, so as to realize the simultaneousdisplay of a first display sub-substrate and a second display subsubstrate and the displayed images are distinct. The above scheme inwhich the two source driver chips are disposed may also realize theseparate display of a corresponding display sub-panel or thedouble-sided simultaneous display by cooperation with a gate drivecircuit and by one of the source driver chips outputting a cutoff signalto a data line connected thereto.

As shown in FIG. 5, the first source driver chip 701 includes aplurality of first output ends (only one of which is shown in FIG. 5)and a plurality of second output ends (only one of which is shown inFIG. 5) in some embodiments. The first output ends of the first sourcedriver chip 701 are electrically connected to the first data lines 116in a one-to-one correspondence way and the second output ends of thereofare electrically connected to the second data lines 216 in a one-to-onecorrespondence way. The second source driver chip 702 is electricallyconnected to the second data lines 216. When the same contents aresynchronously displayed by the first display sub-substrate and thesecond display sub-substrate, the second source driver chip 702connected to the second data lines 216 has no signal output, but thefirst source driver chip 701 simultaneously outputs source drive signalsto the first data lines 116 and the second data lines 216, respectively,through the first output ends and the second output ends, which improvethe consistency of the signals of the first display sub-panel 1 and thesecond display sub-panel 2, and further increases the consistency of thesimultaneous display of the first display sub-panel 1 and the seconddisplay sub-panel 2. In addition, only the first source driver chip 701is required to be turned on upon the synchronous display, which may saveenergy consumption.

As shown in the figures, the light emitting device 8 of the displaypanel may be an OLED (Organic Light Emitting Diode) in some embodiments.As shown in FIGS. 6-8, the first display sub-panel 1 includes a firstgate layer 102 which includes a plurality of first gate lines 101, afirst active layer 103, a first source and drain layer 104, a firstanode layer 105, a first luminescent layer 106, and a first cathodelayer 107, in a direction perpendicular to the spacer layer 4 andpointed to the first display sub-panel 1 from the spacer layer 4. Thesecond display sub-panel 2 includes a second gate layer 202 whichincludes a plurality of second gate lines 201, a second active layer203, a second source and drain layer 204, a second anode layer 205, asecond luminescent layer 206, and a second cathode layer 207, in adirection perpendicular to the spacer layer 4 and directed from thespacer layer 4 to the second display sub-panel 2. The display panelfurther includes a base substrate 6, as shown in FIG. 6. The basesubstrate 6 may be located between the second cathode layer 207 and thesecond anode layer 205. As shown in FIG. 7, the base substrate 6 may belocated between the second gate layer 202 and the second active layer203. As shown in FIG. 8, the base substrate 6 may be located between thefirst gate layer 102 and the second gate layer 202 and the basesubstrate 6 serves as the spacer layer 4. The base substrate 6 may alsobe located between the first cathode layer 107 and the first anode layer105 or the substrate 6 is located between the first gate layer 102 andthe first active layer 103. The above base substrate 6 is used to formvarious functional layers on both sides thereof, respectively. In thisembodiment, only one base substrate 6 needs to be disposed, whichcontributes to the reducing of a thickness of the whole display panelcompared with a conventional double-sided display panel on which twobase substrates 6 are disposed.

The above base substrate 6 may be a rigid base substrate 6 made ofglass, for example, or a flexible base substrate 6 made of polyethylenenaphthalate or polyethylene terephthalate, for example.

In some embodiments, the display panel further includes a first supportmember 108 disposed on a side of the first cathode layer 107 facing awayfrom the base substrate 6, and a second support member 208 disposed on aside of the second cathode layer 207 facing away from the base substrate6. The first and second support members 108 and 208 provide supportbetween the display panel and other components (such as a polarizer)disposed on the outerside of the display panel.

In some embodiments, the first display sub-panel 1 includes a firstliquid crystal cell and the second display sub-panel 2 includes a secondliquid crystal cell, as shown in FIG. 9. The display panel furtherincludes a backlight 9 disposed between the first display sub-panel 1and the second display sub-panels 2 and the backlight 9 can emit lighton both sides thereof and can be used as the spacer layer 4. In adirection perpendicular to the backlight 9 and directed from thebacklight 9 to the first display sub-panel 1, the first displaysub-panel 1 includes a first gate layer 102 which includes a pluralityof first gate lines 101, a first source layer 103, a first source anddrain layer 104, a layer of a first pixel electrode 113 which iselectrically connected to a first drain electrode, a first liquidcrystal layer 114, and a layer of a first common electrode 112. In adirection perpendicular to the backlight 9 and directed from thebacklight 9 to the second display sub-panel 2, the second displaysub-panel 2 includes a second gate layer 202 which includes a pluralityof second gate lines 201, a second source layer 203, a second source anddrain layer 204, a layer of a second pixel electrode 213 which iselectrically connected to a second drain electrode, a second liquidcrystal layer 214, and a layer of a second common electrode 212.

An embodiment of the present disclosure further provides a method formanufacturing a display panel which includes the following steps:

In step S1, a base substrate 6 having a first surface and a secondsurface, which is opposite to the first surface, is provided.

In step S2, a first stacked structure is formed on the first surface.

In step S3, a second stacked structure is formed on the second surface.

The structure consisted of the first stacked structure, the basesubstrate 6 and the second stacked structure include a first displaysub-panel 1 and a second display sub-panel 2 disposed opposite to eachother and a plurality of single-way conducting switches 3. The firstdisplay sub-panel 1 includes a plurality of first gate lines 101 and thesecond display sub-panel 2 includes a plurality of second gate lines201. The first gate lines 101, the second gate lines 201 and thesingle-way conducting switches 3 are provided in one-to-onecorrespondence. Each of the single-way conducting switches 3 includes aninput end which is electrically connected to the first gate line 101corresponding thereto and an output end which is electrically connectedto the second gate line 201 corresponding thereto. Each of thesingle-way conducting switches 3 is unidirectionally conducted from thefirst gate line 101 to the second gate line 201 corresponding thereto.

The method for manufacturing a display panel provided by this embodimentcan achieve a beneficial effect the same as that achieved by theabove-mentioned display panel, which will not be elaborated herein.

In some embodiments, the step in which the first stacked structure isformed on the first surface includes the following steps.

In step S111, a second anode layer 205, a second source and drain layer204, a second active layer 203, a second gate layer 202, and a spacerlayer 4 are sequentially formed on the first surface in this order.

In step S112, a plurality of through-holes 5 are formed in the spacerlayer 4 and the single-way conducting switches 3 are formed in thethrough-holes 5, and are electrically connected to the second gate layer202.

In step S113, a first gate layer 102 which is electrically connected tothe second gate layer 202 via the single-way conducting switch 3, afirst active layer 103, a first source and drain layer 104, a firstanode layer 105, a first luminescent layer 106, and a first cathodelayer 107 are sequentially formed on a side of the through-hole 5 facingaway from the base substrate 6.

The step in which the second stacked structure is formed on the secondsurface includes:

In step S211, a plurality of openings, in which a second luminescentlayer 206 is formed, are formed on the base substrate 6.

In step S212, a second cathode layer 207 is formed on a surface of thesecond luminescent layer 206 facing away from the base substrate 6.

During the forming of the above functional layers, an insulating layeror a passivation layer is also formed between them to perform theinsulation and protection of the functional layers. In specificimplementation, referring to FIG. 6, during the forming of the firststacked structure on the first surface of the base substrate 6, first,the second anode layer 205 is formed on the first surface. Subsequet tothe forming of a desired pattern of the second anode layer 205 by anetching process or the like. A second passivation layer 210 is formed onthe second anode layer 205 and a via-hole is formed at a positioncorresponding to the second anode layer 205 in the second passivationlayer 210. The second source and drain layer 204 is further formed onthe second passivation layer 210 and the second drain electrode isconnected to the second anode layer 205 through the via-hole. Subsequentto the obtaining of the desired pattern of the second source and drainlayer 204 by etching or the like, an insulating layer is formed on thesecond source and drain layer 204, and a via-hole is formed at aposition corresponding to the pattern of the second source and drainlayer 204 in the insulating layer. The second active layer 203 is formedon the insulating layer and the second active layer 203 is connected toa second source electrode and the second drain electrode through thevia-hole in the insulating layer. A second insulating layer 211 isformed on the second active layer 204 and the second gate layer 202 isthen formed on the second insulating layer 211. The spacer layer isformed on the second gate layer 202 subsequent to the forming of thedesired pattern of the second gate layer 202. The through-holes 5 areformed in the spacer layer 4 and the single-way conducting switches 3are formed in the through-holes 5 and are electrically connected to thesecond gate layer 202. The first gate layer 102 is formed on a side ofthe through-hole 5 facing away from the base substrate 6 and a firstinsulating layer 111 is then formed on the first gate layer 102.Thereafter, the first active layer 103 and an insulating layer aresequentially formed on the first insulating layer 111 and a via-hole isformed in the insulating layer. The first source and drain layer 104 isformed on the insulating layer and a first source electrode is connectedto the first active layer 103 through the via-hole while a first drainelectrode is connected to the first active layer 103 through anothervia-hole. A first passivation layer 110 is formed on the first sourceand drain layer 104 and a via-hole is formed at a location correspondingto the first drain electrode in the first passivation layer 110. Thefirst anode layer 105 is formed on the first passivation layer 110 andis connected to the first drain electrode through the via-hole. After adesired pattern for the first anode layer 105 is formed by processessuch as exposure and etching, an insulating layer is formed on the firstanode layer 105 and an opening is formed at a location corresponding toa first anode in the insulating layer. Thereafter, a first pixeldefining layer 109 is formed over the insulating layer and an opening,in which the first luminescent layer 106 is formed, is formed at aposition corresponding to the first anode in the first pixel defininglayer 109. Finally, the first cathode layer 107 is formed on the firstluminescent layer 106.

The fabricated first surface of the base substrate 6 is flipped down toallow the second surface of the base substrate 6 to face upward. Duringthe forming of the second stacked structure on the second surface of thebase substrate 6, a plurality of openings are first formed on the basesubstrate 6 and a second pixel defining layer 209 is formed on thesecond surface of the base substrate 6 and openings are also formed atpositions corresponding to the openings of the base substrate 6 in thesecond pixel defining layer 209 and a second luminescent layer 206 isformed in the openings of the base substrate 6 and the second pixeldefining layer 209. Finally, the second cathode layer 207 is formed on asurface of the second luminescent layer 206 facing away from the basesubstrate 6.

Referring to FIG. 7, in some embodiments, the step in which the firststacked structure is formed on the first surface includes the followingsteps.

In step S121, a second gate layer 202 and a spacer layer 4 aresequentially formed on the first surface.

In step S122, a plurality of through-holes 5 are formed in the spacerlayer 4 and a plurality of single-way conducting switches 3 are formedin the through-holes 5 and are electrically connected to the second gatelayer 202.

In step S123, a first gate layer 102, a first active layer 103, a firstsource and drain layer 104, a first anode layer 105, a first luminescentlayer 106, and a first cathode layer 107 are sequentially formed on aside of the through-holes 5 facing away from the base substrate 6,wherein the first gate layer 102 is electrically connected to the secondgate layer 202 through the single-way conducting switch 3.

The step in which the second stacked structure is formed on the secondsurface includes the following steps.

In step S221, a second active layer 203, a second source and drain layer204, a second anode layer 205, a second luminescent layer 206, and asecond cathode layer 207 are sequentially formed on the second surface.

In the steps above, a plurality of insulating layers or passivationlayers are also formed during the forming of the functional layers and aprinciple for the forming of the layers refers to the description of theforming of the layers in the embodiment shown in FIG. 6.

Referring to FIG. 8, in some embodiments, the step of forming the firststacked structure on the first surface includes the following steps.

In step S131, a plurality of through-holes 5 are formed in the basesubstrate 6 and a plurality of single-way conducting switches 3 areformed in the through-holes 5.

In step S132, a first gate layer 102, a first active layer 103, a firstsource and drain layer 104, a first anode layer 105, a first luminescentlayer 106, and a first cathode layer 107 are sequentially formed on thefirst surface, wherein the first gate layer 102 is electricallyconnected to the single-way conducting switches 3.

The step of forming the second stacked structure on the second surfaceincludes the following steps.

In step S231, a second gate layer 202, a second active layer 203, asecond source and drain layer 204, a second anode layer 205, a secondluminescent layer 206 and a second cathode layer 207 are sequentiallyformed on the second surface, wherein the second gate layer 202 iselectrically connected to the single-way conducting switches 3.

An embodiment of the present disclosure further provides a method fordriving a display panel, which is used for driving the display panel asdescribed above. The driving method includes: when a first displaysub-panel 1 and a second display sub-panel 2 are simultaneouslydisplayed, inputting a first gate scan signal to a first gate line 101of the first display sub-panel 1 and enabling the display of the firstdisplay sub-panel 1; and the first gate scan signal driving acorresponding single-way conducting switch 3 to be unidirectionallyturned on from the first gate line 101 to a second gate line 201 of thesecond display sub-panel 2, and allowing the simultaneous display of thesecond display sub-panel 2 and the first display sub-panel 1. The methodfor driving a display panel provided by this embodiment can achieve abeneficial effect the same as that achieved by the above-mentioneddisplay panel, which will not be elaborated herein.

Hereinafter, the driving method for the display panel will be describedin detail by taking an example in which the gate drive circuit is a GOAunit. The technical solution of the gate drive circuit serving as a gatedriver chip is also included in the protection scope of the presentdisclosure.

In specific implementation, a first GOA unit provides a first gate scansignal to a first gate line 101 while a second GOA unit outputs nosignal or a cutoff signal to a second gate line 201, so that asingle-way conducting switch 3 has a voltage difference between bothends thereof and the single-way conducting switch 3 is unidirectionallyconducted from the first gate line 101 to the second gate line 201 ofthe second display sub-panel 2, so as to synchronize the input of thefirst gate scan signal to the second gate line 201 with that to thefirst gate line 101 and achieve the simultaneous display of the firstdisplay sub-panel 1 and the second display sub-panel 2.

In order to better ensure the stabilization of a signal pressure ofsecond gate electrodes connected to the second gate lines 201 during thesynchronous display, in some embodiments, the second display sub-panel 2further includes a plurality of voltage stabilizing resistors R whichare disposed in a wiring area of the second display sub-panel 2, asshown in FIG. 1. The voltage stabilizing resistors R and the single-wayconducting switches 3 are disposed in one-to-one correspondence and eachof the voltage stabilizing resistors R has one end which is electricallyconnected to the second GOA unit corresponding thereto and the other endwhich is electrically connected to the output end of the single-wayconducting switch 3 corresponding thereto. When the simultaneous displayof the first display sub-panel 1 and the second display sub-panel 2 isperformed, a first gate scan signal is input to the first gate lines 101of the first display sub-panel 1, to enable the display of the firstdisplay sub-panel 1. The voltage stabilizing resistors R are conductedand the first gate scan signal drives the single-way conducting switch 3corresponding thereto to be unidirectionally conducted from the firstgate line 101 to the second gate line 201 of the second displaysub-panel 2, so as to achieve the synchronous display of the seconddisplay sub-panel and the first display sub-panel. That is to say, afirst gate scan signal is outputted from the first GOA units, but nosignal or only a cutoff signal is outputted from the second GOA units.The single-way conducting switch 3 corresponding to them, at this time,has a voltage difference between its input end and output end, so thesingle-way conducting switch 3 is turned on. When there is no voltagestabilizing resistor R provided, since no signal or only a cutoff signalis outputted from the second GOA units, voltage at the output end of thesingle-way conducting switch 3 is pulled down and voltage of each of thesecond gate electrodes to which the second gate line 201 is connected ispulled down to be lower than a turn-on voltage of the second gateelectrode, so that the second gate electrode cannot be turned on. When avoltage stabilizing resistor R is provided, the voltage stabilizingresistor R remains conducted when the synchronous display is performed.A appropriate type of resistor may be selected to maintain voltageinputted to each of the second gate electrodes at an appropriate value,which is neither higher than voltage of the first gate scan signal tounable to conduct the single-way conducting switch nor lower than theturn-on voltage of each of the second gate electrodes, so as to ensurethe normal turn-on of each of the second gate electrodes and smoothlyrealize the double-sided synchronous display.

In some embodiments, the driving method further includes: when the firstdisplay sub-panel 1 and the second display sub-panel 2 display differentscreens, inputting a first gate scan signal V₁ to the first gate line101 of the first display sub-panel 1 to realize the display of a firstscreen of the first display sub-panel 1; inputting a second gate scansignal V₂ to the second gate line 201 of the second display sub-panel 2and V₁−V₂<V_(on), wherein V_(on) is a forward turn-on voltage of thesingle-way conducting switch 3 and the second display sub-panel 2displays a second screen. In specific implementation, the first gatescan signal V₁ may be input to the first gate lines 101 by the first GOAunits in a one-to-one correspondence way while the second gate scansignal V₂ may be input to the second gate lines 201 by the second GOAunits in a one-to-one correspondence way. When V₁−V₂<V_(on), thesingle-way conducting switch 3 cannot be reversely conducted, the firstgate electrodes connected to the first gate lines 101 are turned on andthe second gate electrodes connected to the second gate lines 201 areturned on. A first data signal is input to first data lines 116 througha first source starting chip in the first display sub-panel 1 and asecond data signal is input to second data lines 216 through a secondsource starting chip in the second display sub-panel 2, so as to realizethe simultaneous display of the two display sub-panels to displaydifferent screens.

In some embodiments, the driving method for the display panel furtherincludes: when the first display sub-panel 1 displays a screen but thesecond display sub-panel 2 displays no screen, inputting a first gatescan signal to the first gate line 101 of the first display sub-panel 1to allow the first display sub-panel 1 to display a first screen; andinputting a cutoff signal to the second gate line 201 of the seconddisplay sub-panel 2 to pull down a signal on the second gate line 201and, thus, the second display sub-panel 2 does not display any screen.In a specific implementation, the display panel further includes aplurality of short-circuit branches 217 disposed in the wiring area ofthe second display sub-panel 2. The short-circuit branches 217 aredisposed in one-to-one correspondence to the voltage stabilizingresistors R and each of the short-circuit branches 217 is connected inparallel to both ends of the voltage stabilizing resistor Rcorresponding thereto. The second display sub-panel 2 further includes aplurality of second data lines 216. Two output ends are disposed in thesecond GOA unit, wherein the first output end is connected to thevoltage stabilizing resistor R and the second output end is connected tothe short-circuit branch 217. On or off of the first output end and thesecond output end is controlled by a circuit and a clock signal withinthe second GOA unit, so as to control turn-on or turn-off of the voltagestabilizing resistor R and the short-circuit branch 217. When theshort-circuit branch 217 is conducted, the voltage stabilizing resistorR is short-circuited and since the second GOA unit has no signal outputor only outputs a cutoff signal, voltage at the output end of thesingle-way conducting switch 3 is pulled down, so that voltage of thesecond gate electrodes connected to the second gate lines 201 is pulleddown. When the voltage is lower than the turn-on voltage of the secondgate electrodes, the second gate electrodes cannot be turned on, so thatthe second display sub-panel 2 fails to display a screen, but the firstGOA unit normally inputs a first gate drive signal to the first gatelines 101, to allow the normal display of a screen of the first displaysub-panel 1.

It should be noted that in an embodiment in which a short-circuit branch217 are provided, upon the simultaneous display of the first displaysub-panel 1 and the second display sub-panel 2, the voltage stabilizingresistor R is conducted but the short-circuit branch 217 is disconnectedso as to ensure the normal operation of the voltage stabilizing resistorR.

When the first display sub-panel 1 displays a screen but the seconddisplay sub-panel 2 does not display any screen, a first gate scansignal may be input to the first gate line 101 of the first displaysub-panel 1 to enable the display of a first screen of the first displaysub-panel 1, however, the second data line 216 of the second displaysub-panel 2 has no signal input thus the second display sub-panel 2fails to display any screen. That is to say, the first GOA unit suppliesa first gate scan signal to the first gate line 101 and the first sourcedriver chip 701 supplies a first data signal to the first sourceelectrode connected to the first data line 116, to realize the displayof the first display sub-panel 1. The second GOA unit supplies a secondgate scan signal to the second gate line 201 and the second sourcedriver chip 702 does not supply any data signal to the second sourceelectrode connected to the second data line 216, so the display of thesecond display sub-panel 2 is not performed.

In some embodiments, the driving method further includes: when the firstdisplay sub-panel 1 does not display any screen, but the second displaysub-panel 2 displays a screen, inputting no signal or a cutoff signal V₃to the first gate line 101 of the first display sub-panel 1; inputting asecond gate scan signal V₂ to the second gate line 201 of the seconddisplay sub-panel 2, wherein a difference of V₂−V₃ is less than areverse breakdown voltage of the single-way conducting switch 3, so thedisplay of the second display sub-panel 2 is performed. That is to say,the first GOA unit outputs no signal or a cutoff signal V₃ to the firstgate line 101 corresponding thereto, but the second GOA unit outputs asecond gate scan signal V₂ to the second gate line 201 correspondingthereto. The single-way conducting switch 3 corresponding to the secondgate line 201, at this time, is not conducted, and the difference ofV₂−V₃ is smaller than the reverse breakdown voltage of the single-wayconducting switch 3, so the display of a screen of the second displaysub-panel 2 is performed, but the display of a screen of the firstdisplay sub-panel 1 is not performed.

An embodiment of the present disclosure also provides a display deviceincluding the display panel as described above. The display device maybe an OLED display device, a liquid crystal display device, a PM-OLED(Passive Matrix Organic Light Emitting Diode) display device, an AM-OLED(Active Matrix Organic Light Emitting Diode) display device, aMicro-OLED (Organic Light Emitting Diode Microdisplay Technology)display device, a QLED (Quantum Dot Light Emitting Diodes) displaydevice, and the like. During specific implementation, the display devicemay be products or components having a display function such as mobilephones, tablets, televisions, monitors, notebook computers, digitalphoto frames, and navigators which perform a double-sided display.

The display device provided by the embodiment of the present disclosurecan achieve a beneficial effect the same as that achieved by theabove-mentioned display panel, which will not be elaborated herein.

The above-described contents are only specific embodiments of thepresent disclosure and the protection scope of the present disclosure isnot limited thereto. Any person skilled in the art can easily think ofchanges or substitutions that fall into the protection scope of thepresent disclosure within the technical scope of the disclosure of thepresent disclosure. Therefore, the protection scope of the presentdisclosure should be determined by the protection scope of the claims.

What is claimed is:
 1. A system, comprising: a display panel,comprising: a first display sub-panel and a second display sub-paneldisposed opposite to each other, the first display sub-panel comprisinga plurality of first gate lines and the second display sub-panelcomprising a plurality of second gate lines; a plurality of single-wayconducting switches, one correspondence one of the plurality of firstgate lines, one of the plurality of second gate lines, and one of theplurality of single-way conducting switches being connected and disposedin a one-to-one correspondence; and wherein one of the single-wayconducting switches has an input end electrically connected to thecorresponding first gate line and an output end electrically connectedto the corresponding second gate line, and one of the single-wayconducting switches is unidirectionally conducted from the correspondingfirst gate line to the corresponding second gate line.
 2. The systemaccording to claim 1, wherein the single-way conducting switch comprisesa P-N junction, the P-N junction comprises a P-region connected to thecorresponding first gate line and an N-region connected to thecorresponding second gate line.
 3. The system according to claim 1,wherein the display panel further comprises a spacer layer disposedbetween the first display sub-panel and the second display sub-panel,the spacer layer being provided with a plurality of through-holes,wherein the through-holes correspond to the single-way conductingswitches one by one and correspond to wiring areas of the first displaysub-panel and the second display sub-panel; one of the single-wayconducting switches is located in a corresponding through-hole; or thesingle-way conducting switches are located in the wiring area of thefirst display sub-panel, and the output end of each of the single-wayconducting switches is electrically connected to the correspondingsecond gate line through the corresponding through-hole; or thesingle-way conducting switches are located in the wiring area of thesecond display sub-panel, and the input end of each of the single-wayconducting switches is electrically connected to the corresponding firstgate line through the corresponding through-hole.
 4. The systemaccording to claim 3, wherein the first display sub-panel furthercomprises a plurality of first Gate Driver on Array (GOA) units disposedin the wiring area of the first display sub-panel, the first GOA unitsbeing electrically connected to the first gate lines in a one-to-onecorrespondence way; the second display sub-panel further comprises aplurality of second GOA units disposed in the wiring area of the seconddisplay sub-panel, the second GOA units being electrically connected tothe second gate lines in a one-to-one correspondence way; and the inputend of each of the single-way conducting switches being electricallyconnected to a corresponding first GOA unit and first gate line and theoutput end of each of the single-way conducting switches beingelectrically connected to the corresponding second gate line.
 5. Thesystem according to claim 4, wherein: the second display sub-panelfurther comprises a plurality of voltage stabilizing resistors disposedin the wiring area of the second display sub-panel, the voltagestabilizing resistors and the single-way conducting switches beingdisposed in one-to-one correspondence; one of the voltage stabilizingresistors has one end electrically connected to a corresponding secondGOA unit and another end electrically connected to the output end of thecorresponding single-way conducting switch; and a plurality ofshort-circuit branches disposed in the wiring area of the second displaysub-panel, the short-circuit branches being disposed in one-to-onecorrespondence to the voltage stabilizing resistors and one of theshort-circuit branches being connected in parallel to both ends of thecorresponding voltage stabilizing resistor.
 6. The system according toclaim 3, wherein: in a direction perpendicular to the spacer layer anddirected to the first display sub-panel from the spacer layer, the firstdisplay sub-panel comprises a first gate layer which comprises the firstgate lines, a first active layer, a first source and drain layer, afirst anode layer, a first luminescent layer and a first cathode layer;in a direction perpendicular to the spacer layer and directed from thespacer layer to the second display sub-panel, the second displaysub-panel comprises a second gate layer which comprises the second gatelines, a second active layer, a second source and drain layer, a secondanode layer, a second luminescent layer and a second cathode layer; thedisplay panel further comprises a base substrate, wherein the basesubstrate is located between the second cathode layer and the secondanode layer; or, the base substrate is located between the second gatelayer and the second active layer; or, the base substrate is locatedbetween the first gate layer and the second gate layer and the basesubstrate serves as the spacer layer; or, the base substrate is locatedbetween the first cathode layer and the first anode layer; or, the basesubstrate is located between the first gate layer and the first activelayer.
 7. The system according to claim 3, wherein the first displaysub-panel comprises a first liquid crystal cell and the second displaysub-panel comprises a second liquid crystal cell; and the display panelfurther comprises a backlight disposed between the first displaysub-panel and the second display sub-panels and the backlight is capableof emitting light on both sides thereof and is used as the spacer layer.8. The display panel according to claim 1, wherein: the first displaysub-panel further comprises a plurality of first data lines and thesecond display sub-pane further comprises a plurality of second datalines; the display panel further comprises a first source driver chipand a second source driver chip, the first source driver chip beingelectrically connected to the first data lines and the second sourcedriver chip being electrically connected to the second data lines; andthe first source driver chip comprising a plurality of first output endsand a plurality of second output ends, the first output ends of thefirst source driver chip being electrically connected to the first datalines in a one-to-one correspondence way and the second output ends ofthe first source driver chip being electrically connected to the seconddata lines in a one-to-one correspondence way; the second source driverchip being electrically connected to the second data lines.
 9. A methodfor manufacturing a display panel, comprising: providing a basesubstrate having a first surface and a second surface, which is oppositeto the first surface; forming a first stacked structure on the firstsurface; forming a second stacked structure on the second surface,wherein a structure consisted of the first stacked structure, the basesubstrate and the second stacked structure comprises a first displaysub-panel and a second display sub-panel disposed opposite to each otherand a plurality of single-way conducting switches, wherein: the firstdisplay sub-panel comprises a plurality of first gate lines and thesecond display sub-panel comprises a plurality of second gate lines; oneof the plurality of first gate lines, one of the plurality of secondgate lines, and one of the plurality of single-way conducting switchesare connected and disposed in a one-to-one correspondence; one of thesingle-way conducting switches comprises an input end which iselectrically connected to the corresponding first gate line and anoutput end which is electrically connected to the corresponding secondgate line; and one of the single-way conducting switches isunidirectionally conducted from the first gate line to the second gateline corresponding thereto.
 10. The method for manufacturing a displaypanel according to claim 9, wherein the forming a first stackedstructure on the first surface comprises: sequentially forming a secondanode layer, a second source and drain layer, a second active layer, asecond gate layer and a spacer layer on the first surface; forming aplurality of through-holes in the spacer layer and forming thesingle-way conducting switches in the through-holes, the single-wayconducting switches being electrically connected to the second gatelayer; sequentially forming a first gate layer, a first active layer, afirst source and drain layer, a first anode layer, a first luminescentlayer and a first cathode layer on a side of the through-hole facingaway from the base substrate, the first gate layer being electricallyconnected to the second gate layer via the single-way conducting switch;and the step of forming the second stacked structure on the secondsurface comprises: forming a plurality of openings on the base substrateand forming a second luminescent layer in the openings; forming a secondcathode layer on a surface of the second luminescent layer facing awayfrom the base substrate.
 11. The method for manufacturing a displaypanel according to claim 9, wherein the forming a first stackedstructure on the first surface comprises: sequentially forming a secondgate layer and a spacer layer on the first surface; forming a pluralityof through-holes in the spacer layer and forming the single-wayconducting switches in the through-holes, the single-way conductingswitches being electrically connected to the second gate layer;sequentially forming a first gate layer, a first active layer, a firstsource and drain layer, a first anode layer, a first luminescent layerand a first cathode layer on a side of the through-holes facing awayfrom the base substrate, the first gate layer being electricallyconnected to the second gate layer through the single-way conductingswitch; and the step of forming the second stacked structure on thesecond surface comprises: sequentially forming a second active layer, asecond source and drain layer, a second anode layer, a secondluminescent layer and a second cathode layer on the second surface. 12.The method for manufacturing a display panel according to claim 9,wherein the forming a first stacked structure on the first surfacecomprises: forming a plurality of through-holes in the base substrateand forming the single-way conducting switches in the through-holes;sequentially forming a first gate layer, a first active layer, a firstsource and drain layer, a first anode layer, a first luminescent layerand a first cathode layer on the first surface, the first gate layerbeing electrically connected to the single-way conducting switches; andthe step of forming the second stacked structure on the second surfacecomprises: sequentially forming a second gate layer, a second activelayer, a second source and drain layer, a second anode layer, a secondluminescent layer and a second cathode layer on the second surface, thesecond gate layer being electrically connected to the single-wayconducting switches.
 13. A driving method for driving a display panel,comprising: providing the display panel, the display panel comprising: afirst display sub-panel and a second display sub-panel disposed oppositeto each other, the first display sub-panel comprising a plurality offirst gate lines and the second display sub-panel comprising a pluralityof second gate lines; and a plurality of single-way conducting switches,one of the plurality of first gate lines, one of the plurality of secondgate lines, and one of the plurality of single-way conducting switchesbeing connected and disposed in a one-to-one correspondence, wherein oneof the single-way conducting switches has an input end electricallyconnected to the corresponding first gate line and an output endelectrically connected to the corresponding second gate line, and one ofthe single-way conducting switches is unidirectionally conducted fromthe corresponding first gate line to the corresponding second gate line;when the simultaneous display of the first display sub-panel and thesecond display sub-panel is performed, inputting a first gate scansignal to the first gate line of the first display sub-panel andenabling the display of the first display sub-panel; and driving, by thefirst gate scan signal, the corresponding single-way conducting switchto be unidirectionally turned on from the first gate line to the secondgate line of the second display sub-panel, and allowing the simultaneousdisplay of the second display sub-panel and the first display sub-panel.14. The driving method according to claim 13, wherein the second displaysub-panel comprises a plurality of voltage stabilizing resistors whichare disposed in the wiring area of the second display sub-panel, thevoltage stabilizing resistors and the single-way conducting switchesbeing in one-to-one correspondence and one of the voltage stabilizingresistors having one end which is electrically connected to thecorresponding second GOA unit and the other end which is electricallyconnected to the output end of the corresponding single-way conductingswitch; and wherein the driving method further comprises: when thesimultaneous display of the first display sub-panel and the seconddisplay sub-panel is performed, inputting a first gate scan signal tothe first gate line of the first display sub-panel and enabling thedisplay of the first display sub-panel; and conducting the voltagestabilizing resistor and the first gate scan signal driving thecorresponding single-way conducting switch to be unidirectionallyconducted from the first gate line to the second gate line of the seconddisplay sub-panel, and allowing the simultaneous display of the seconddisplay sub-panel and the first display sub-panel.
 15. The drivingmethod according to claim 13, further comprising: when the first displaysub-panel and the second display sub-panel display different screens,inputting a first gate scan signal V₁ to the first gate line of thefirst display sub-panel to realize the display of a first screen of thefirst display sub-panel; and inputting a second gate scan signal V₂ tothe second gate line of the second display sub-panel and V₁−V₂<V_(on),wherein V_(on) is a forward turn-on voltage of the single-way conductingswitch and the second display sub-panel displays a second screen. 16.The driving method according to claim 13, further comprising: when thefirst display sub-panel displays a screen but the second displaysub-panel displays no screen, inputting a first gate scan signal to thefirst gate line of the first display sub-panel to allow the firstdisplay sub-panel to display a first screen; inputting a cut-off signalto the second gate line of the second display sub-panel to pull down asignal on the second gate line and thus the second display sub-paneldoes not display any screen; or, inputting a first gate scan signal tothe first gate line of the first display sub-panel to allow the firstdisplay sub-panel to display a first screen; inputting no data signal tothe second display sub-panel so the second display sub-panel does notdisplay any screen.
 17. The driving method according to claim 13,further comprising: when the first display sub-panel does not displayany screen, but the second display sub-panel displays a screen,inputting no signal or a cut-off signal V₃ to the first gate line of thefirst display sub-panel; and inputting a second gate scan signal V₂ tothe second gate line of the second display sub-panel, wherein adifference of V₂−V₃ is less than a reverse breakdown voltage of thesingle-way conducting switch, so the display of the second displaysub-panel is performed but the display of the first display sub-panel isnot performed.
 18. The system according to claim 1, further comprising adisplay device, the display device comprising the display panel.
 19. Thesystem according to claim 2, further comprising a display device, thedisplay device comprising the display panel.
 20. The system according toclaim 3, further comprising a display device, the display devicecomprising the display panel.